Radical changes to chlamydial taxonomy are not necessary just yetWe, the undersigned, strongly object to the proposed reclassification of the order Chlamydiales (Everett et al., 1999). It should not be accepted at this stage. That Chlamydia psittaci and Chlamydia trachomatis each comprised a heterogeneous group of organisms lumped into two species was recognized when those species were first designated. However, these organisms were placed into a single genus based on DNA homology, and a set of convenient, relatively easily assayed biological properties. The need for further speciation in the future was recognized, but workers in the field delayed reclassification waiting for identification of taxonomically significant biological properties. This was the basis for classifying Chlamydia pneumoniae as a separate species. One of our major concerns is that this new classification scheme, based almost exclusively on minor sequence differences in 16S and 23S rRNA genes, has no new biological markers for genus or species differentiation. Some of the new species include too few isolates to be confident that these small differences will be maintained as more isolates are evaluated. There is increasing agreement among microbial taxonomists that while 16S rRNA is useful for evolutionary studies, it is not always the best choice for speciation. Genus-specific genes would be better.Even if there is a case for more chlamydial species, the same cannot be said for the division into two genera. Everett et al. (1999) arbitrarily define that a sequence should be 95 % identical to be included in the respective genus. Given that maximum differences between C. trachomatis, C. psittaci and C. pneumoniae strains are between 5 and 6 % (i.e. 94 % identity), their proposal to establish separation at the genus level is unwarranted. Recent 16S rRNA evaluation by Tanner et al. (1999), found that the C. trachomatis, C. psittaci, Chlamydia pecorum and C. pneumoniae strains represent a taxonomically and phylogenetically coherent grouping into one genus. Thus there is not sufficient sequence difference that compels a division of the genus. This begs the question, do we need a new genus right now ? The answer is, it is completely unnecessary ! The new genus designation ignores the unique, highly conserved biology shared by these organisms that is recognized when they are in a single genus. The single genus Chlamydia worked. It has taken years to educate public health workers, funding agencies and the public about these organisms called Chlamydia. Chlamydia is now a well-recognized name. To change the name would create confusion (even among scientific colleagues). We don't dispute the sequence data, but question its use as the sole criterion to create a new genus. The proposal does not address how one is to identify isolates of Chlamydiales beyond identifying gene sequences. There are no commonly determined biological differences between the organisms within both proposed genera. Unfortunately, several biological markers described by Everett et ...
Proteins from purified elementary bodies of Chlamydia trachomatis were separated by two-dimensional gel electrophoresis on nonlinear wide-range immobilized pH gradients in the first dimension and polyacrylamide gradient gels in the second dimension. The maps obtained with this system are highly reproducible and resolve ca. 600 spots. By using immunoblot analysis with specific antibodies and/or N-terminal amino acid sequencing, we established the map positions of a number of described chlamydial proteins, such as the major outer membrane protein (MOMP) the 60 kDa cystein-rich outer membrane protein (OMP2), the DnaK-like, GroEL-like, and macrophage infectivity potentiator (MIP)-like proteins, the plasmid-encoded pgp3 protein, two ribosomal proteins (S1 and L7/L12), and the protein-elongation factor EF-Tu. Other proteins, for which gene assignment was not possible, have been identified by three parameters (Mr, pI and N-terminal sequence). This work provides a preliminary basis for a future and progressive compilation of a genome-linked database of chlamydial proteins.
We constructed the physical map of Chlamydia trachomatis serovar L2 by using three restriction endonucleases, NotI (GC[GGCCGC), SgrAI (C(A/G)[CCGG(T/G)G), and Sse8387I (CCTGCA[GG), and we analyzed the fragments by pulsed-field gel electrophoresis. A total of 25 restriction endonuclease sites and 13 genes and/or operons were located on the map. The genome size was determined to be 1,045 kb. Neither highly transcribed chlamydia genes nor developmental cycle-specific genes were clustered on the genome.
The synthesis of early proteins from Chlamydia trachomatis serovar L2 was analyzed by two-dimensional gel electrophoresis. By pulse-label experiments, the synthesis of seven proteins was observed at 2 to 8 h postinfection before the major outer membrane protein was detected at 8 to 10 h after infection. The early proteins were synthesized throughout the 30-h period investigated, but the synthesis of three proteins of 75, 62, and 45 kilodaltons decreased from 26 to 30 h postinfection. Pulse-chase analysis showed that the signals from the same three proteins declined 26 to 30 h after infection. Three of the early proteins were identified as the S1 ribosomal protein, the GroEL-like protein, and DnaK-like protein, respectively.
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